An electrostatic filter and a rack for filter plates of an electrostatic filter

ABSTRACT

The invention relates to a rack ( 21, 27, 28 ) for supporting electrostatic filter plates ( 22, 23 ) of an electrostatic filter ( 20 ). The rack ( 21, 27, 28 ) is an elongated member comprising a plurality of notches ( 11 ) on a longitudinal side of the rack ( 21, 27, 28 ) for supporting a plate ( 22, 23 ) arranged to a notch ( 11 ). The rack ( 21, 27, 28 ) further comprises a slot ( 26 ) for adhesive arranged to be used at least for attaching the plates ( 22, 23 ) to the rack ( 21, 27, 28 ). The slot ( 26 ) is arranged on the opposite side of the rack ( 21, 27, 28 ) than notches ( 11 ). There is also an opening ( 24 ) in the first group of plates ( 22 ) at that point where the plates ( 22 ) are aligned with the voltage supply rack ( 28 ) but which are not attached to that rack ( 28 ). The invention further relates to an electrostatic filter ( 20 ) comprising a plurality of racks.

TECHNICAL FIELD

The present invention relates to a rack to be used in an electrostaticfilter structure. Furthermore, the invention relates to an electrostaticfilter comprising several racks.

BACKGROUND

Different kind of electrostatic precipitators (ESP) are used forseparating particles from an air stream. An air purification devicecomprising such a filter is commonly marketed to the public. An airpurification device can be, for example, arranged in an air duct or itmay be a portable device. These filters comprise a particle chargingunit and a particle collector unit. The particle charging unitcomprises, for example, at least one corona wire or corona needle forionizing or charging the particles existing in the air stream with anelectronic charge. The particle collector unit comprises anelectrostatic plate stack that is arranged downstream relative to theparticle charging unit. In the particle collector unit an electricalfield is produced by plates charged with an opposite electrical charge.Charged particles are collected and removed from the air stream whenthey pass through the stack of plates of the particle collector unit andcollide with the plates. Plates are usually made of metal or suitablepolymer material and arranged into frame structures as stack of plates.

SUMMARY

It is an aim of the present invention to provide a rack that is asupporting rack suitable to be used in a filter structure and to providea filter structure comprising a plurality of racks as a supportingstructure for plates. The rack may also act as a voltage connectingmean.

According to a first embodiment, there is provided a rack for supportingfilter plates of a frameless filter and supplying electric voltage. Therack is an elongated member comprising a plurality of notches on alongitudinal side of the rack for supporting a plate arranged to a notchand comprising a connecting structure in both ends of the rack forconnecting the rack to supporting structures of the frameless filter.The rack further comprises a slot for adhesive arranged to be used atleast for attaching the plates to the rack. The slot is arranged on theopposite side of the rack than notches.

According to an embodiment, the rack is made of plastic. According to anembodiment, the rack is made of electrically non-conductive material.According to an embodiment, the rack is made of electrically conductivematerial. According to an embodiment, the filter plates are arranged tobe attached to the rack by adhesive in the slot. According to anembodiment, the rack is further arranged to act as an electric voltagesupply rack for filter plates. According to an embodiment, the filterplates are arranged to be attached to the rack by electricallyconductive adhesive. According to an embodiment, the supportingstructures are covers above and under the frameless electrostaticfilter. According to an embodiment, the rack further comprises at leastone electrical connector.

According to a second embodiment, there is provided a framelesselectrostatic filter comprising a plurality of racks and a plurality ofelectrically conductive filter plates arranged as a stack one on theother. The rack is an elongated member comprising a plurality of notcheson a longitudinal side of the rack for supporting a plate arranged to anotch. The rack further comprises a slot for adhesive arranged to beused at least for attaching the plates to the rack. The slot is arrangedon the opposite side of the rack than notches.

A first part of the filter plates are arranged into a first electricpotential and a second part of the filter plates are arranged into asecond electric potential. A first part of the racks are arranged tosupport only the first part of the filter plates and a second part ofthe racks are arranged to support only the second part of the filterplates so that each rack supports a plurality of filter plates and eachplate is supported by a plurality of racks. Every other filter plate ofthe stack is arranged into the first electric potential and every otherinto the second electric potential so that an electric field is formedbetween filter plates. There is an opening in the plates at that pointwhere the plates are aligned with a rack, but are not arranged to beattached to that rack, and wherein at least one rack of the first partof the racks is arranged to supply first electric voltage to the firstpart of the plates and at least one rack of the second part of the racksis arranged to supply second electric voltage to the second part of theplates, wherein the second electric voltage may mean grounding of thesecond part of the plates. The frameless electrostatic filter comprisesa supporting structure above and under the filter

According to an embodiment, the rack is made of plastic. According to anembodiment, the rack is made of electrically non-conductive orconductive material. According to an embodiment, the filter plates arearranged to be attached to the rack by adhesive in the slot. Accordingto an embodiment, the rack that is further arranged to act as anelectric voltage supply rack for filter plates. According to anembodiment, the filter plates are arranged to be attached to the rack byelectrically conductive adhesive. According to an embodiment, the rackfurther comprises a connecting structure in both ends of the rack forconnecting the rack to a supporting structure on an electrostaticfilter. According to an embodiment, electrically conductive adhesive isused in a slot of racks arranged to provide electric voltage for plates.According to an embodiment, electrically non-conductive adhesive is usedfor attaching plates to a slot of racks arranged to support plates.According to an embodiment, the rack further comprises at least oneelectrical connector. According to an embodiment, the filter has a shapeof rectangular, cubic, half oval, oval, triangular, a half circle orcircular. According to an embodiment, the filter is suitable to beconnected to another electrostatic filter for forming a combinedelectrostatic filter having a shape of rectangular, cubic, oval,triangular or circular. According to an embodiment, the filter issuitable to be connected to another electrostatic filter so that aright-angle is formed so that both electrostatic filters form a half ofthe corner structure of the combined electrostatic filter. According toan embodiment, racks arranged to provide electric voltage for plates arearranged inside the combined electrostatic filter.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following, various embodiments of the invention will be describedin more detail with reference to the appended drawings, in which

FIG. 1 shows a rack of an electrostatic filter of an air purificationdevice according to an embodiment of the invention in a perspectiveview;

FIG. 2a, b shows parts of an electrostatic filter according to anembodiment of the invention in a perspective view;

FIG. 3a shows a part of an electrostatic filter according to anembodiment of the invention in a perspective view;

FIG. 3b shows an electrostatic filter according to an embodiment of theinvention in a perspective view;

FIG. 4 shows a part of an electrostatic filter according to anembodiment of the invention from above;

FIG. 5a-b show prior art voltage supply connections of an electrostaticfilter;

FIG. 5c shows voltage supply connections of a combined electrostaticfilter according to an embodiment of the invention from above; and

FIG. 6a-f show filters and combined filter structures according to anembodiment of the invention from above.

DETAILED DESCRIPTION

An example of a filter structure according to embodiments of theinvention is an electrostatic filter, for example, an electrostaticprecipitator (ESP) suitable to be used in an air purification device ora gas filter. In this connection, the air purification device may be asupply air device, an air cleaning device, an air conditioning device orany other device using a filtering structure for separating and removingparticles and other impurities from a gas stream. The gas stream may be,for example, an air stream.

An electrostatic filter structure according to the invention for an airpurification device comprises at least one particle charging unit and atleast one electrostatic filter. The particle charging unit may comprise,for example, at least an ionizer i.e. a corona charger, for example, oneor more corona needles or one or more corona wires for ionizing orcharging the particles existing in the gas stream with an electriccharge. It is also possible that other type of particle charging is usedinstead of corona wires or needles. The particle charging unit may alsorefer to a device installed on the upstream of the filter i.e. frontside of the filter or a device which is integrated in the filter. Theair flow entering the filter is ionized before it enters the actualelectrostatic filter of the electrostatic filter structure so that theparticles in the gas stream that are electrically charged can thus beremoved from the gas stream by means of the electrostatic filter. A highvoltage ionizer charging the particles of gas stream flowing through theelectrostatic filter can also produce minimal amounts of ozone. At thesesmall levels it should not increase system corrosion or lead toincreased allergen levels or asthma. However, when corona needles areused instead of corona wires it is possible that even smaller amounts ofozone are produced. The particle charging unit according to anembodiment of the invention may comprise, for example, at least one, butalso 2 to 8 or even more corona needles.

The electrostatic filter itself according to embodiments of theinvention is a particle collector unit comprising two groups ofplate-like elements i.e. electrostatic filter plates arrangedessentially parallel between each other at a predetermined distance fromeach other and essentially parallel to the flow direction of a gasstream arranged to be purified by the electrostatic filter structure andflowing through the electrostatic filter, past the plates. Plates ofboth groups are electrically conductive plates that are made of, forexample, electrically conductive plastic or other suitable material. Afirst group of plates is arranged into a first electric potential and asecond group of plates is arranged into a second electric potential sothat there is a potential difference between two adjacent plates and anelectric field is formed between two adjacent plates. The formedpotential difference may be, for example, 4 kV-10 kV. For example, ifthe first electric potential is earth, the second electric potential maybe negative or positive high voltage or vice versa or if the firstelectric potential is negative high voltage, the second potential may bepositive high voltage, or vice versa. Plates that are arranged intonegative or positive high voltage are connected to a corresponding DChigh voltage source, for example, −4 kV to −10 kV or +4 kV to +10 kV.Plates that are arranged into earth potential are connected to a groundvoltage source i.e. plates are grounded. Plates of the second group ofplates are electrically separated compared to the first group of plates.There is a voltage difference between the plates of the first group andthe second group and an electric field is formed between plates. Theplates are charged and grounded so that in a case of an electricallyconductive rack, the rack is connected to the voltage source. But ifelectrically conductive adhesive is arranged in the slot of anelectrically conductive rack, it is possible that the rack is connectedto the voltage source and/or electrically conductive adhesive isconnected to the voltage source. Whereas, if electrically conductiveadhesive is arranged in the slot of a non-conductive rack, the adhesiveis connected to the voltage source. It is possible that both ends of therack are connected to the voltage source.

Plates of an electrostatic filter form a stack, wherein every secondplate of the stack is in the first electric potential and every secondplate is in the second electric potential. Electrically chargedparticles of the gas stream are attracted to the plates with differentcharge, also referred to as collection plates. If particles arepositively charged, they are collected by negatively charged plates orgrounded plates of the filter and if particles are negatively charged,they are collected by positively charged plates or grounded plates. Inother words, charged particles are led into the filter, in which theseparation of the particles from the gas stream is effected primarily byelectric forces of an electric field. In order to hold the concentricelements at the appropriate distance apart and electrically insulatedand/or in order to provide a DC voltage supply and/or ground connection,racks according to the invention are used.

A rack according to the invention is a supporting structure for platesmade of electrically conductive or non-conductive material, for example,plastic or other suitable material, for example, activated carbon orother material that is coated by some suitable material. A rackaccording to the invention may be used for supporting plates and/or alsoas a voltage supply mean. The material used may depend on the intendeduse of the rack in question; for example, for a supporting structurenon-conductive material may be used whereas for a voltage supply rackelectrically conductive material may be used. However, in some cases itmay be possible to use electrically conductive material for a supportingstructure and electrically non-conductive material for a voltage supplyrack, if electrically conductive adhesive is used. The electricallyconductive adhesive may be any material suitable to be used in a slot ofthe rack for attaching the plates to the rack.

The rack has an elongated shape and it comprises a plurality of notcheson a longitudinal side of the rack. The notches are arrangedperpendicular to the longitudinal direction of the rack. An edge of aplate may be arranged, for example, to every other notch of the rack sothat plates are one on the other if similar racks are used forsupporting plates in both potentials. Or plates may be arranged to everynotch of the rack, if racks are formed so that racks supporting platesin the first electric potential have notches in different height thanracks supporting plates in the second electric potential and plates indifferent potentials settle so that overlapping plates are in differentpotential. Each plates supported by the same rack are arranged into thesame electric potential. Plates may be attached in place to the rack byelectrically non-conductive adhesive if the rack is made of electricallynonconductive material, and by electrically conductive adhesive, if therack is made of electrically conductive material. The adhesive may bemade of electrically conductive or non-conductive material, for example,plastic that is smelted before it is arranged to a slot of the rack. Thematerial of adhesive may be the same material as the material of therack. The slot is on the opposite side of the rack than notches. Theslot may extend from a first end area of the longitudinal rack to thesecond end area of the rack. Usually, the slot may not extend to thevery ends of the rack, because the rack further comprises a connectingstructure in both ends of the rack for connecting the rack to asupporting structure on an electrostatic filter. The slot may bearranged at that point of the rack comprising the notches. The adhesivemay be used for fastening the plates to the rack. And when the rack andadhesive are made of resistive material that is electricallynon-conductive, the plates that are attached to the rack are insulatedfrom each other, but when the rack and/or adhesive are electricallyconductive, the plates are arranged to the same electric potential.

In an electrostatic filter there is a plate arranged in the secondelectric potential between two plates in the first electric potentialthat are arranged in the rack. For example, if plates arranged in therack are grounded i.e. in the first electric potential, the platebetween the grounded plates is charged in to the second electricpotential. The plates in the second electric potential are also attachedto the rack, which is different than where the grounded plates areattached to. Furthermore, in order to avoid accidental coupling of theplates having different potentials, there is an opening in the plates atthat points where the plates are aligned with racks but are not arrangedto be attached to them. This means that the plate that is not arrangedto be attached to the rack is clearly arranged apart from the rack i.e.there is a distance between an edge of the plate and the rack into whichthe plate is not arranged to be attached. The distance between the plateand the rack is arranged such that the breakdown voltage is not exceededand/or that other electrical leakages are minimised. Possible distancemay be for example, 1-15 mm, for example, 4 mm. The distance betweenoverlapping plates may be the same as the distance between theunconnected plate and rack. Therefore, due to the opening it is lesslikely that unintentional coupling happens between the overlappingplates being in different potential even if the moisture accumulates orplates get dirty. The filter structure according to the embodiments ofthe invention has an improved ability to cope with moisture and dirtaccumulating on the plates and racks, because parts, for example, platesin different potentials will not come into contact despite theaccumulated moisture and dirt. Each plate may be connected to severalracks arranged in a distance from each other. There may be a rackcomprising plates in the second electric potential between those rackscomprising plates in the first electric potential. Racks are asupporting structure arranged to support the plates so that they staywithin the desired distance from plates above and/or below it, but theyalso makes the filtering structure sturdy and keep it in shape.

In addition to supporting, a rack according to an embodiment of theinvention may act as a voltage supply mean i.e. as a voltage connectingstructure as already stated above. The desired DC voltage can be broughtto the plates connected to the rack by using electrically conductiveadhesive in a slot of an electrically conductive or non-conductive rackor if the rack is made of electrically conductive material, it may bepossible that there is no need to use electrically conductive adhesivein a slot of the rack or adhesive at all, but the electricallyconductive rack acts as a voltage connecting structure as such. The rackacting as a voltage connecting structure is then connected to anelectric source i.e. DC voltage source providing the desired voltage forplates. The desired potential may be for example the ground or avoltage, for example, between 4 kV-10 kV or −4 kV-−10 kV.

It should be noted that a rack according to embodiments of the inventionmay be further arranged to support other type of plate like elements,for example, activated carbon filter plates or plastic, ceramic,metallic etc. plates which are coated, instead of or in addition toelectrostatic filter plates so that a gas filter is formed. Also theseplates, when attached to the rack, are arranged essentially as a stackat a predetermined distance from each other and essentially parallel tothe flow direction of gas flow arranged to be purified by gas filter andflowing through the gas filter, past the plates. The gas filter issuitable to purify different type of impurities from the gas flow.

FIG. 1 shows a rack 10 for an electrostatic filter of an airpurification device according to an embodiment of the invention in aperspective view. The rack 10 is a longitudinal member made ofelectrically non-conductive or conductive material, for example,plastic, depending on the intended use of the rack. In a firstlongitudinal side of the rack 10 comprises a plurality of notches 11arranged perpendicular to the longitudinal direction of the rack 10.Electrostatic filter plates are arranged to be positioned and attachedinto at least a part of these notches 11, for example, to every secondnotch 11, and perpendicular to the longitudinal direction of the rack.Every plate that is attached to the rack is arranged to the sameelectric potential. The opposite longitudinal side of the rack 10, thesecond longitudinal side, comprises a slot 12 for adhesive. The adhesivemay be electrically non-conductive adhesive arranged to attach theplates in place. However, when the adhesive is used, in addition to orinstead of attaching the plates, as an electric connector through whichthe electric potential is provided to plates, the adhesive in the slot12 is electrically conductive. Both ends of the rack 10 comprise aconnecting structure 13. The connecting structure 13 is used forconnecting the rack 10 to a supporting structure on an electrostaticfilter. It is also possible that there is no need to use adhesive in theslot 12 in some embodiments of the invention.

FIG. 2a shows a part of an electrostatic filter 20 according to anembodiment of the invention in a perspective view. The electrostaticfilter 20 comprises several electrically non-conductive racks 21, 27 forsupporting plates. A first part of racks 21 is arranged to supportplates of a first group 22 and a second part of racks 27 is arranged tosupport plates of a second group 23, wherein plates of the first group22 are arranged in the first electric potential and the second group 23are arranged in the second electric potential, wherein the firstelectric potential is different than the second electric potential. Ascan be seen from FIG. 2 a, plates of the first group 22 are attached toa first part of the racks 21, and plates of the second group 23 areattached to a second part of the racks 27. There is an opening 24 in aplate 22, 23 at that point where the plate 22, 23 is aligned with therack 27, 21 but is not attached to that. One plate 22, 23 usuallycomprises several openings 24. Ends of the racks 21 comprise aconnecting structure 25 arranged to be connected to a supportingstructure (not shown) of the electrostatic filter 20.

Plates 22, 23 may be attached in place in the racks 21, 27 by usingelectrically non-conductive adhesive in a slot 26 of the racks 21, 27arranged on the opposite side of the rack 21, 27 from the notches. Theadhesive fastens the plates on place.

Plates of both groups 22, 23 are electrically conductive plastic plates.The distance between the overlapping plates is arranged such that theair can flow through plates 21, 27 and an adequate electric field can beprovided between plates 21, 27.

FIG. 2b shows a bigger part of the electrostatic filter 20 according toan embodiment of the invention in a perspective view. In this embodimentthere is also shown a rack 28 used for supplying electric voltage forthe second group of plates 23. There is also an opening 24 in the firstgroup of plates 22 at that point where the plates 22 are aligned withthe voltage supply rack 28 but which are not attached to that rack 28.The adhesive used in the slot of the voltage supply rack 28 iselectrically conductive.

FIG. 3a shows a part of an electrostatic filter 30 according to anembodiment of the invention in a perspective view. The electrostaticfilter 30 comprises several racks 31, a voltage supply rack 32 a forarranging the plates that are attached to it into a first electricpotential, a voltage supply rack 32 b for arranging the plates that areattached to it into a second electric potential, and a cover 33 intowhich connecting means of the racks 31, 32 a, 32 b are attached. Thecover 33 is made of electrically non-conductive material, for example,electrically non-conductive plastic. There is also a corresponding cover(not shown) into which connecting means of the other ends of the racks31, 32 a, 32 b are attached. The filter 30 may be used as such or it maybe used as a part of a larger electrostatic filter entity i.e. acombined electrostatic filter comprising more than one electrostaticfilter, for example, filters corresponding to the electrostatic filter30 of FIG. 3 a. The combined electrostatic filter acts still as a oneelectrostatic filter. The shape of an electrostatic filter may also beother than shown in the embodiments of the invention. It may be, forexample rectangular.

FIG. 3b shows a combined electrostatic filter according to an embodimentof the invention in a perspective view. The combined electrostaticfilter 35 comprises four similar separate electrostatic filters 30corresponding to electrostatic filters 30 shown in FIG. 3 a. The shapeof electrostatic filters 30 is such that they are suitable to bearranged in a box-like-shape i.e. as a quadrangle, wherein each of thefour sides is an electrostatic filter 30. Electrostatic filters 30 maybe connected to each other in different ways so that different combinedfilter shapes are formed, the electrostatic filters 30 may be arranged,for example, one next to each other, or there may be only 2 or 3 filtersin a larger electrostatic filter. The combined electrostatic filter 35comprising more than one separate electrostatic filters 30 may also beformed in shape in which it is arranged to be used at the place of use.This offers the advantage that the storage and transportation ofcombined electrostatic filters 35 comprising more than one separateelectrostatic filters 30 is easier and cheaper. Other examples ofpossible shapes of electrostatic filters and combined electrostaticfilters according to embodiments of the invention are show in FIG. 6a-f. An electrostatic filter may be connected to at least one otherelectrostatic filter by any suitable connecting device. The connectingdevice may be, for example, a clip, glue, tape, Velcro, magnet,pin-hole-device etc.

FIG. 4 shows a part of an electrostatic filter according to anembodiment of the invention from above. In this embodiment is shown acorner structure of a combined electrostatic filter 40 comprising twoseparate electrostatic filters 44, 45 that are connected together.Because the structure of the electrostatic filters 44, 45 is such that aright-angle may be formed so that both electrostatic filters 44, 45 forma half of the corner structure of the combined electrostatic filter 40and because the electrostatic filters 44, 45 do not comprise a framestructure surrounding the electrostatic filters 44, 45, the air may flowthrough the whole corner structure of the electrostatic filter 40relatively unrestricted and therefore substantially the whole cornerstructure of the combined electrostatic filter 40 may filter the airflow. This kind of corner structure provides more surface area for thecombined electrostatic filter 40. The larger surface area providesbetter filtering efficiency. Furthermore, this kind of corner structureis a structure that does not enable air to flow past the combined filter40 like some existing corner structures of filters i.e. air cannot flowthrough the combined filter 40 without being filtered.

FIGS. 5a and 5b show prior art voltage supply connections of anelectrostatic filter. Traditionally voltage supply connections arearranged on the outer or inner surface of an electrostatic filter. Inthe FIG. 5 a, the supply connections 51 are arranged on the outersurface of the electrostatic filter 50, which may not work properly,because the supply connections 51 may easily and unintentionally be inconnection with metallic structures of an air purification device insidewhich the electrostatic filter 50 is arranged. Therefore, this structuremay lead to problems. In the FIG. 5 b, the supply connections 54 arearranged on the inner surface of the electrostatic filter 53.

In this case, the non-purified gas stream touches the supply connections54 on its way to the electrostatic filter 53 for purifying via anopening 55 formed in the middle of the filter parts of the filter 53towards the outer surfaces of the filter parts. The particles may foulthe supply connections 54, which may lead to a short circuit or shortcircuits. Short circuits are more likely formed when particles absorbmoisture in them. It should be noted that also structure of FIG. 5a maylead to unwanted short circuits, when air touches the supply connections51 on its way to the electrostatic filter 50 for purifying from theoutside of the filter 51 towards the interior of the filter 50

FIG. 5c shows voltage supply connections 57 of a combined electrostaticfilter 56 according to an embodiment of the invention from above. Inthis embodiment the voltage supply connections 57 are arranged, asvoltage supply racks, inside the electrostatic filter 56. This ispreferable, because now the voltage supply connections 57 do not foul ortouch to the metallic structures of an air purification device insidewhich the electrostatic filter 56 is arranged. Furthermore, when voltagesupply connections 57 are arranged inside the electrostatic filter 56moisture and dirt accumulating on racks is less.

FIGS. 6a-f show filters and combined filter structures according toembodiments of the invention from above. FIG. 6a shows a rectangularcombined electrostatic filter 60 according to an embodiment of theinvention. The combined electrostatic filter 60 comprises four separateelectrostatic filters, two of them are larger electrostatic filters 61and two are smaller electrostatic filters 61′. Filters of a combinedelectrostatic filter do not need to be same size or shape. FIG. 6b showsan electrostatic filter 62 according to an embodiment of the inventionhaving a shape of a half circle. It is possible to combine this filterto other electrostatic filter also having a shape of half circle so thata circle combined filter is formed. FIG. 6c shows an electrostaticfilter 63 according to an embodiment of the invention having a shape ofa circle. FIG. 6d shows an electrostatic filter 64 according to anembodiment of the invention having a shape of a half oval. It ispossible to combine this filter to other electrostatic filter havingalso a shape of a half oval so that an oval combined filter is formed.FIG. 6e shows an electrostatic filter 66 according to an embodiment ofthe invention having a shape of an oval. FIG. 6f shows a combinedelectrostatic filter 68 according to an embodiment of the inventionhaving a shape of a triangular. The combined electrostatic filter 68comprises three separate electrostatic filters 69 that are connected toeach other.

It should be noted that the shape of an electrostatic filter and acombined electrostatic filter may be freely selected according tointended use and/or location of an electrostatic filter and a combinedelectrostatic filter. The shape is no limited any way.

In addition to the above-mentioned it is possible to add, for example,by adhesive, an electrical connector to one or more notches of a rackand/or to at least one end or side of the rack.

It is obvious that the present invention is not limited solely to theabove-presented embodiments, but it can be modified within the scope ofthe appended claims.

1. A rack for supporting filter plates of a frameless filter andsupplying electric voltage, wherein the rack (10) is an elongated membercomprising a plurality of notches (11) on a longitudinal side of therack (10) for supporting a plate arranged to a notch (11), andcomprising a connecting structure (13) in both ends of the rack (10) forconnecting the rack (10) to supporting structures of the framelessfilter, and wherein the rack (10) further comprises a slot (12) foradhesive arranged to be used at least for attaching the plates to therack (10), and which slot (12) is arranged on the opposite side of therack (10) than notches (11).
 2. A rack according to claim 1, wherein therack (10) is made of plastic.
 3. A rack according to claim 1 or 2,wherein the rack (10) is made of electrically non-conductive material.4. A rack according to claim 1 or 2, wherein the rack (10) is made ofelectrically conductive material.
 5. A rack according to any of claim 1to 4, wherein the filter plates are arranged to be attached to the rack(10) by adhesive in the slot (12).
 6. A rack according to any of claim 1to 5, wherein the rack (10) that is further arranged to act as anelectric voltage supply rack for filter plates.
 7. A rack according toclaim 6, wherein the filter plates are arranged to be attached to therack (10) by electrically conductive adhesive.
 8. A rack according toany of claim 1 to 7, wherein the rack (10) further comprises at leastone electrical connector.
 9. A frameless electrostatic filter (20)comprising a plurality of racks (21, 27) according to any of claims 1 to8 and a plurality of electrically conductive filter plates (22, 23)arranged as a stack one on the other, and wherein a first part of thefilter plates (22) are arranged into a first electric potential and asecond part of the filter plates (23) are arranged into a secondelectric potential, and wherein a first part of the racks (21) arearranged to support only the first part of the filter plates (22) and asecond part of the racks (27) are arranged to support only the secondpart of the filter plates (23) so that each rack (21, 27) supports aplurality of filter plates (22, 23) and each plate (22, 23) is supportedby a plurality of racks (21, 27), and wherein every other filter plate(22) of the stack is arranged into the first electric potential andevery other plate (23) into the second electric potential so that anelectric field is formed between filter plates (22, 23), and whereinthere is an opening (24) in the plates (22, 23) at that point where theplates (22, 23) are aligned with a rack (21, 27) but are not arranged tobe attached to that rack (21, 27), and wherein at least one rack of thefirst part of the racks (21) is arranged to supply first electricvoltage to the first part of the plates (22) and at least one rack ofthe second part of the racks (27) is arranged to supply second electricvoltage to the second part of the plates (23), and wherein theelectrostatic filter (20) comprises a supporting structure above andunder the filter (20).
 10. An electrostatic filter according to claim 9,wherein electrically conductive adhesive is used in a slot (26) of racks(21, 27) arranged to provide electric voltage for plates.
 11. Anelectrostatic filter according to claim 9 or 10, wherein electricallynon-conductive adhesive is used for attaching plates to a slot (26) ofracks (21, 27) arranged to support plates (22, 23).
 12. An electrostaticfilter according to any of claim 9 to 11, wherein the filter (20) isconnected to another electrostatic filter for forming a combinedelectrostatic filter.
 13. An electrostatic filter according to claim 12,wherein the filter (20) is connected to another electrostatic filter sothat a right-angle is formed so that both electrostatic filters form ahalf of the corner structure of the combined electrostatic filter. 14.An electrostatic filter according to claim 12 or 13, wherein racks (32a, 32 b) arranged to provide electric voltage for plates (22, 23) arearranged inside the combined electrostatic filter.